http://orcid.org/0000-0002-3246-2993
Figures
Abstract
Background
Chronic fluid overload is common in patients with chronic kidney disease (CKD) and can with time lead to poor prognosis regarding to the cardiovascular events. Serum NT-proBNP and OH/ECW might reflect fluid status of the patients, and the maximal tricuspid regurgitation velocity (TRVmax) could reflect systolic pulmonary artery pressure (SPAP). We investigated the relationship between markers of volume status and marker of pulmonary hypertension (PH) in non-dialysis CKD5 (CKD5-ND) patients.
Methods
Bioimpedance spectroscopy (BIS), echocardiography, and measurement of serum NT-proBNP were performed in 137 consecutive patients on the same day. TRVmax greater than or equal to 2.9 m/s, corresponding to SPAP of approximately 36 mmHg, was used as a definition of the possibility of PH in the absence of left heart disease and chronic respiratory disease (PH group).
Results
Patients with possibility of PH (TRVmax ≥ 2.9 m/s) was found in 27 (19.70%) patients. Among the values obtained from BIS, those reflecting the fluid balance (OH, OH/ECW, and E/I ratio) were significantly higher in the PH group. The OH/ECW in patients with PH were significantly higher than those patients without (26.76 ± 15.07 vs. 13.09 ± 15.05, P < 0.001). NT-proBNP was also significantly higher in PH group compared to the non-PH group (median = 10,112 pg/ml, IQR = 30,847 pg/ml vs. median = 1,973 pg/ml, IQR = 7,093 pg/ml, P < 0.001). OH/ECW was positively associated with TRVmax (r = 0.235, P = 0.006). Multivariate logistic regression revealed that increased OH/ECW and serum NT-proBNP were significantly associated with an increased risk of PH.
Conclusions
A significant number of patients showed increased TRVmax, which was closely related to volume status in CKD5-ND patients. Echocardiography and BIS could be important players in a high possibility of PH detection and treatment in asymptomatic CKD patients. Therefore, these measures could be helpful to improve the cardiac outcomes after initiating renal replacement therapy. Further research may be needed to validate the consistency of this association across other stages of CKD.
Citation: Han B-G, Kim J, Jung IY, Son J-W (2019) Relationship between volume status and possibility of pulmonary hypertension in dialysis naive CKD5 patients. PLoS ONE 14(9): e0221970. https://doi.org/10.1371/journal.pone.0221970
Editor: Pierre Delanaye, University of Liège, BELGIUM
Received: April 17, 2019; Accepted: August 19, 2019; Published: September 3, 2019
Copyright: © 2019 Han et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Data Availability: All relevant data are within the paper and its Supporting Information files.
Funding: The author(s) received no specific funding for this work.
Competing interests: The authors have declared that no competing interests exist.
Abbreviations: DBP, diastolic blood pressure; eGFR, estimated glomerular filtration rate; ECW, extracellular water; ICW, intracellular water; LAVI, left atrium volume index; LVEDD, left ventricular end-diastolic dimension; LVEDV, left ventricular end-diastolic volume; LVDD, left ventricular diastolic dysfunction; LVEF, left ventricular ejection fraction; LVMI, left ventricular mass index; NT-proBNP, N-terminal pro-hormone of brain natriuretic peptide; OH, overhydration; PH, pulmonary hypertension; SBP, systolic blood pressure; SPAP, systolic pulmonary artery pressure; TBW, otal body water; TRV, tricuspid regurgitation velocity
Introduction
Pulmonary hypertension (PH) is a disease that can progress to right heart failure, whatever the cause, and associated with a poor prognosis [1]. Recently, it has been recognized as a novel threat to end stage renal disease (ESRD) patients and has become a subject of much interest. However, its pathogenesis has not been completely elucidated. The reported prevalence of PH in chronic kidney disease (CKD) patients, mostly undergoing hemodialysis, widely varied and increased with the decline of renal function [2]. The rate of PH was 33.7% - 52% in hemodialysis patients [3–6] and 12.6% - 42% in peritoneal dialysis patients [7–9]. However, there has not been many studies conducted with CKD patients without dialysis treatment, and the reported range of prevalence was 8.3% -71% [2, 4, 10–15]. The prevalence of PH increased with longer duration of dialysis treatment [10].
The prevalence of PH varies between reports due to the lack of consideration of fluid overload and the stage of CKD [16]. Fluid overload represents a crucial step in the pathophysiological pathways to PH in CKD patients. Assessment of volume status in patients with renal insufficiency is important not only for short-term volume management but also for long-term prevention of cardiovascular disease. Fluid overload is one of the predictors of mortality and morbidity. However, the traditional methods have several limitations for detecting the degree and severity of overhydration [17]. Recently, bioimpedance spectroscopy (BIS) performed at the bedside has gained popularity because it is a non-invasive, quick and relatively affordable method to quantitatively assess the volume status of the patient, although only a small number of studies have examined the relationship between volume status and PH [6, 8, 18, 19]. We previously reported that increased E/e´ ratio, reflecting left ventricular diastolic dysfunction (LVDD), was strongly associated with fluid overload in CKD patients [20]. LVDD may contribute to the development of PH by causing an elevated left atrial pressure [14].
Herein, we particularly focused on the relationship between volume status, estimated by multi-frequency bioimpedance and NT-proBNP, and PH in dialysis naive CKD5 patients.
Materials and methods
Patients and data collection
This study was initiated after receiving approval from the Institutional Review Board of Yonsei University Wonju Severance Christian Hospital (institutional review board no. CR 318087) and enrolled only the patients who provided written informed consent prior to the study. This study is an observational cross-sectional and prospective study of patients hospitalized for a renal replacement therapy plan. BIS, echocardiography, and laboratory tests were performed at the same time before the first dialysis, either hemodialysis or peritoneal dialysis. Patients with liver cirrhosis (n = 1), infection (n = 1), atrial fibrillation (n = 2), and valvular heart disease (n = 1) were excluded from the analysis. Patients (n = 8) with left ventricular ejection fraction (LVEF) less than 45% were also excluded. None of the patients had chronic respiratory disease. 137 patients were finally included in the analysis. This study was conducted in accordance with the Declaration of Helsinki.
Echocardiographic assessment
Echocardiography was performed in the harmonic imaging mode using a 3-MHz transducer and commercial ultrasound system (Vivid-7; General Electric-Vingmed, Milwaukee, WI, USA). A TRV was recorded from the parasternal or apical window with the continuous wave Doppler probe. The left atrial (LA) dimension was measured by 2D-guided M-mode echocardiography using the parasternal short-axis view at the base of the heart. Three LA dimensions were used to calculate the LA volume as an ellipse using the formula: LA volume = (π/6)(SA1×SA2×LA), where SA1 is the M-mode LA dimension, and SA2 and LA are measurements of the short- and long-axis with the apical four-chamber view at ventricular end-systole, respectively. The LA volume index (LAVI) was calculated by dividing LA volume by body surface area (BSA) using the formula as follows: BSA = 0.007184 × weight0.425× height0.725 (m2). LV internal dimensions, LV wall thickness, and LVEF, measured using the biplane modified Simpson rule, according to the previously reported recommendations [21]. LV mass was calculated following American Society of Echocardiography recommendations as LV mass (g) = 1.04×([PWTd+SWTd+LVDd]3×[LVEDD]3)×0.8+0.6, where PWTd and SWTd are the posterior and septal wall thickness at end-diastole respectively, and LVEDD is the M-mode LV dimension with the short axis view at end-diastole. To correct for body surface area, the LV mass index (LVMI) was calculated as LV mass/BSA. As recommended by the Heart Failure and Echocardiography Associations of European Society of Cardiology, both conventional and tissue Doppler imaging (TDI) echocardiographic techniques were used for the evaluation of LV diastolic function [22].
The maximal TRV (TRVmax) greater than or equal to 2.9 m/s, corresponding to systolic pulmonary artery pressure (SPAP) of approximately 36 mmHg, was used as a definition of a high possibility of PH (PH group) [23]. Echocardiography was performed by trained cardiologists who were completely blinded to the patient information. The intra-class correlation coefficient of intra- and inter-observer variability in measurement of TRVmax was 98.9% and 98.0%.
Assessment of the volume status
Bioimpedance spectroscopy using the BCMTM (Body Composition MonitoringTM, Fresenius Medical Care, Bad Homburg, Germany) was performed prior to any dialysis treatment. BCMTM utilizes alternating electric currents across 50 different frequencies from 5 to 1000 kHz for the measurement of fluid status. Extracellular water (ECW), intracellular water (ICW) and total body water (TBW) were automatically calculated. The overhydration (OH) value can be calculated from the difference between the normal ECW and actual measured ECW [24]. OH/ECW greater than or equal to 15% was defined as fluid overload [20]. Patients were in supine position. Disposable electrode patches were used for all measurements.
Laboratory evaluations
All laboratory studies were performed before the first dialysis application. NT-proBNP, which is known to reflect volume status, was also measured, and the association with the possibility of PH was analysed. NT-proBNP was measured using electrochemiluminescence immunoassay (ECLIA) on Modular analytics E170 (Roche Diagnostics, Mannheim, Germany). The analytical measurement range for NT-proBNP was 5 to 35,000 pg/mL. In the correlation analysis, it was not appropriate to use the NT-proBNP value because accurate values of less than 5 pg/mL or greater than 35,000 pg/mL could not be obtained. Therefore, patients were divided into three groups in accordance with tertiles of NT-proBNP for the analysis.
Statistical analysis
All analyses were performed with IBM Statistics Package for the Social Science version 23.0 (IBM Corporation, Armonk, NY, USA). The study population characteristics are presented as the mean ± SD, median (IQR), or total number (percentage). Based on the results of TRVmax, the patients were categorized into two groups according to the presence of the possibility of PH. Differences in clinical variables between the two groups were tested with two-sample t-test for continuous variables. The nominal variables were compared using Chi-square test or Fisher’s exact test as appropriate. Pearson’s correlation analysis was used to examine correlations between TRVmax and other variables such as volume markers (OH/ECW, NT-proBNP) and echocardiographic variables. Multivariate logistic regression models was used to examine the associations of OH/ECW and NT-proBNP with TRVmax. The C-statistics was utilized to test the predictive accuracy of a logistic regression model. Goodness of fit for model was assessed using the Hosmer-Lemeshow test, whereby we considered a value of P < 0.05 to indicate that the model had a poor fit. In this analysis, we adjusted for age and sex (model 1) and for diuretics use and albumin (model 2). Finally, a receiver operating characteristic (ROC) curve was created to establish cut-off values of OH and OH/ECW that discriminate patients with TRVmax ≥ 2.9 m/s from those with TRVmax < 2.9 m/s. Statistical significance was defined as P < 0.05.
Results
Patients’ characteristics
The characteristics of the study population are shown in Table 1. Patients with the possibility of PH (TRVmax ≥ 2.9 m/s) were less commonly treated with diuretics (P = 0.006). PH group had significantly lower estimated glomerular filtration rate. The age and gender were similar. The mean age of male and female patients was 59.99 ± 13.09 years and 59.90 ± 11.80 years, respectively. The median [interquartile range (IQR)] OH and OH/ECW were 2.0 (0.5–5.2) L and 13.48 (4.11–27.70) %, respectively. The median NT-proBNP was 2,570.0 (759.2–9,200.5) pg/ml.
Differences according to TRVmax
Among the BIS parameters, extracellular water/intracellular water ratio (E/I ratio), ECW, OH, and OH/ECW were significantly greater in PH group. Serum parameters were not different between the two groups except iPTH and NT-proBNP (Table 2). NT-proBNP was significantly higher in patients with the possibility of PH compared to those without PH. Among the echocardiographic parameters, the LA dimension, LAVI, E velocity, and E/e´ ratio were significantly greater in PH group, while the A velocity, e´ velocity, and LVEF were not significantly different.
Correlation between laboratory, echocardiographic parameters and markers of volume status
TRVmax was correlated with volume marker (OH, OH/ECW, E/I ratio). OH/ECW was significantly associated with LAVI, E velocity, E/e´ ratio, LVEDD, and LVEDV (Table 3).
Multivariate analysis using logistic regression
Among the significantly different variables between the two groups, OH/ECW and NT-proBNP were associated with TRVmax in unadjusted model. These variables were chosen considering the collinearity among the factors. OH/ECW was divided into two groups: OH/ECW <15%, and OH/ECW ≥15% (fluid overload). We also categorized NT-proBNP as tertiles (<1,204.62 pg/mL, 1,204.62~6,931.55 pg/mL, >6,931.55 pg/mL). Odds ratio was calculated using the lowest tertile as the reference.
The fluid overloaded group showed significant odds ratio in model 2 whereas the highest NT-proBNP group showed significant odds ratio in model 1 and model 2 (Table 4). The Hosmer–Lemeshow tests showed significant goodness of fit for model 1 (P = 0.061) and model 2 (P = 0.958). Model 2 showed high capacity for predicting the high risk of PH group. The c-statistic was 0.769 (95% CI 0.676 ~0.861, P < 0.001) and 0.788 (95% CI 0.695 ~0.880, P < 0.001) for model 1 and model 2, respectively.
Discussion
The pathogenesis of PH in ESRD patients is still complex and not completely understood. Several factors, such as fluid overload, arteriovenous fistula, anemia, hypoalbuminemia, cardiac dysfunction, mineral bone disease (MBD), uremic vasculopathy, and non-biocompatible dialysis membranes, have been proposed for the development of PH in dialysis patients [8, 25–27]. Different from other previous reports, albumin and hemoglobin levels and markers of CKD-MBD were not associated with the possibility of PH in this study [9, 28]. In addition, because the patients were dialysis naïve CKD, the arteriovenous fistulae and dialysis membrane components, which were associated with PH in other studies, were excluded in this study [14, 15, 29, 30].
Serum NT-proBNP levels is a biochemical marker for estimating the volume status and is associated with LV diastolic dysfunction [31]. In the present study, we found that E/e´ ratio, a marker of diastolic dysfunction, was associated with volume status and significantly correlated with NT-proBNP and TRVmax. Tissue Doppler e´ velocity, which is an element of E/e´ ratio, was related to TRVmax but not to OH/ECW and NT-proBNP. E velocity was associated with TRVmax, OH/ECW, and NT-proBNP, and there was a significant difference between the patients with or without PH, whereas e´ velocity was not. These findings are in line with the study that E velocity is associated with the circulating volume of hemodialysis patients [32]. On the other hand, A velocity was not related to all three factors. Diastolic dysfunction may contribute to the development of PH by causing an elevated left atrial pressure [12, 14, 23]. Progressive fluid overload with diastolic dysfunction could increase pulmonary capillary wedge pressure, which may result in PH. The right ventricle with thin muscle equipment usually operates at low blood pressure and is not able to tolerate high vascular resistance. Once the right heart chambers lose their distensibility due to an elevated left atrial pressure, it leads to tricuspid regurgitation and further right heart volume overload [33]. PH might be induced and/or aggravated by left heart disease. Because we excluded patients with systolic dysfunction, the main factor would probably be the diastolic dysfunction. Therefore, volume overload is critical to determining TRVmax.
Since the symptoms and signs of PH are somewhat ambiguous, nephrologists rarely suspect PH at the beginning of treatment in the patients with CKD [34]. Clinically, an indication of diuretic therapy is given when the patient complains of the signs and symptoms of fluid overload. It is not common clinical practice to prophylactically administer diuretics prior to diagnosis of PH. Nevertheless, in this study, diuretics were given to many PH patients (88.9%). However, as this study was conducted retrospectively, we could not confirm whether there was a need for the clinicians to prescribe diuretics in suspicion of PH. Furthermore, patients with PH demonstrated more frequent diabetes, and 95% (19 patients) of these patients were on diuretics. Endothelial dysfunction and increased arterial stiffness may occur in early diabetic CKD and so forth fluid overload may occur subsequently and have an effect on left ventricular systolic and/or diastolic dysfunction in late diabetic CKD. Therefore, the authors conclude that the presence of diabetes may have an effect on PH, but the numbers of cases included in this study are small so further studies and analysis with larger numbers of patients, divided into the early and late stage, is needed. In general, the diagnosis of PH can be made in collaboration with a cardiologist with the consideration of two things. The first is that the right heart catheterization should be performed by a skillful specialist because of the invasive nature of the procedure, and the need for a special space equipped with special instruments. The second issue is whether volume control can improve PH, because volume overload is a modifiable factor. However, when CKD5 patients initiate incident dialysis, a comprehensive approach should be implemented because there are factors that can induce PH other than fluid overload.
We could not confirm the change of SPAP by volume control after initiating dialysis. However, since volume control is a reversible factor, improvement of PH can be expected by correcting it. In fact, Yilmaz et al. reported that the SPAP, OH/ECW, and the frequency of PH were significantly reduced after hemodialysis treatment [6]. BIS can be useful as a tool for this, which enables treatments targeting not only PH but also LVDD [35]. An OH/ECW of 15% is thought to represent approximately 2.4 liters of overhydration and is used as a cut-off value for overhydration. In our previous report, the cut-off value for OH and OH/ECW predicting E/e´ ratio greater than 15 was 2.45 liters and 17.28%, respectively [31]. Furthermore, ROC curves were drawn for OH and OH/ECW to determine the cut-off values predicting TRVmax ≥ 2.9 m/s. The area under curve (AUC ± standard error) and cut-off value were as follows: 0.754 ± 0.057 (P < 0.001) and 4.1 liters (sensitivity 74.1%, specificity 80.0%) for OH; 0.746 ± 0.058 (P < 0.001) and 22.66% (sensitivity 74.1%, specificity 80.9%) for OH/ECW (Fig 1). If the fluid overload is above a certain level, it is better to recognize the need for echocardiography and to confirm the presence or absence of PH. Despite the correction of fluid overload with dialysis treatment, it is desirable to consider kidney transplantation rather than dialysis treatment in patients with irreversible PH [36, 37]. At this stage, the role of cardiologist in determining the mode of renal replacement therapy is crucial.
Areas under the curve: OH 0. 754 (95% CI 0.643–0.866) and OH/ECW 0.746 (95% CI 0.633–0.860).
As a limitation of our study, this was a single-center study that included a relatively small number of patients. Furthermore, although SPAP may increase with age and in obesity, weight or body mass index was not adjusted for multivariate logistic regression models. Also, the lack of serial echocardiograms to assess changes in cardiac structure and function over time in relation to the volume control by renal replacement therapy, even though the definition of PH by echocardiography used in this study has limited sensitivity and specificity. Therefore, the mechanism by which fluid overload contributes to PH could not be proven in our study. Finally, although it could have given us important clues to our hypothesis, we did not perform the mandatory procedure, right heart catheterization, for diagnosis confirmation. Despite these limitations, the strength of this study is that we had objectively measured the volume status and concurrently have blindly evaluated SPAP. The study population was relatively homogenous and the patients were mostly enrolled to the study before making the arteriovenous fistula. As far as we know, this is the first study to have attempted in dialysis naïve CKD patients.
Taken together, a significant number of patients showed increased SPAP, which was closely related to volume status in CKD5-ND patients. Therefore, echocardiography and BIS could play an important role in PH detection and treatment of asymptomatic CKD patients. Our study suggests the need for calculation and follow-up of pulmonary artery pressure using Doppler echocardiography in all patients with established CKD5-ND before considering the dialysis treatment. If possible, it is advisable to perform the right heart catheterization in order to confirm PH. These process could be helpful to improve the cardiac outcomes after initiating renal replacement therapy.
Supporting information
S1 File. Dataset: Demographic, laboratory, bioimpedence, and echocardiographic data.
https://doi.org/10.1371/journal.pone.0221970.s001
(XLSX)
References
- 1. Tang M, Batty JA, Lin C, Fan X, Chan KE, Kalim S. Pulmonary hypertension, mortality, and cardiovascular disease in CKD and ESRD patients: A systematic review and meta-analysis. Am J Kidney Dis. 2018;72:75–83 pmid:29429751
- 2. Reque J, Garcia-Prieto A, Linares T, Vega A, Abad S, Panizo N, et al. Pulmonary hypertension is associated with mortality and cardiovascular events in chronic kidney disease patients. Am J Nephrol. 2017;45:107–114 pmid:27941345
- 3. Agarwal R. Prevalence, determinants and prognosis of pulmonary hypertension among hemodialysis patients. Nephrol Dial Transplant. 2012;27:3908–3914 pmid:22290987
- 4. Yigla M, Nakhoul F, Sabag A, Tov N, Gorevich B, Abassi Z, et al. Pulmonary hypertension in patients with end-stage renal disease. Chest. 2003;123:1577–1582 pmid:12740276
- 5. Mahdavi-Mazdeh M, Alijavad-Mousavi S, Yahyazadeh H, Azadi M, Yoosefnejad H, Ataiipoor Y. Pulmonary hypertension in hemodialysis patients. Saudi J Kidney Dis Transpl. 2008;19:189–193 pmid:18310865
- 6. Yilmaz S, Yildirim Y, Taylan M, Demir M, Yilmaz Z, Kara AV, et al. The relationship of fluid overload as assessed by bioelectrical impedance analysis with pulmonary arterial hypertension in hemodialysis patients. Med Sci Monit. 2016;22:488–494 pmid:26874785
- 7. Xu Q, Xiong L, Fan L, Xu F, Yang Y, Li H, et al. Association of pulmonary hypertension with mortality in incident peritoneal dialysis patients. Perit Dial Int. 2015;35:537–544 pmid:25185012
- 8. Unal A, Sipahioglu M, Oguz F, Kaya M, Kucuk H, Tokgoz B, et al. Pulmonary hypertension in peritoneal dialysis patients: prevalence and risk factors. Perit Dial Int. 2009;29:191–198 pmid:19293357
- 9. Kumbar L, Fein PA, Rafiq MA, Borawski C, Chattopadhyay J, Avram MM. Pulmonary hypertension in peritoneal dialysis patients. Adv Perit Dial. 2007;23:127–131 pmid:17886618
- 10. Issa N, Krowka MJ, Griffin MD, Hickson LJ, Stegall MD, Cosio FG. Pulmonary hypertension is associated with reduced patient survival after kidney transplantation. Transplantation. 2008;86:1384–1388 pmid:19034007
- 11. Bolignano D, Rastelli S, Agarwal R, Fliser D, Massy Z, Ortiz A, et al. Pulmonary Hypertension in CKD. Am J Kidney Dis. 2013;61:612–622 pmid:23164943
- 12. Pabst S, Hammerstingl C, Hundt F, Gerhardt T, Grohe C, Nickenig G, et al. Pulmonary hypertension in patients with chronic kidney disease on dialysis and without dialysis: results of the PEPPER-study. PLoS One. 2012;7:e35310 pmid:22530005
- 13. Yigla M, Fruchter O, Aharonson D, Yanay N, Reisner SA, Lewin M, et al. Pulmonary hypertension is an independent predictor of mortality in hemodialysis patients. Kidney Int. 2009;75:969–975 pmid:19212417
- 14. Abdelwhab S, Elshinnawy S. Pulmonary hypertension in chronic renal failure patients. Am J Nephrol. 2008;28:990–997 pmid:18635926
- 15. Havlucu Y, Kursat S, Ekmekci C, Celik P, Serter S, Bayturan O, et al. Pulmonary hypertension in patients with chronic renal failure. Respiration. 2007;74:503–510 pmid:17505128
- 16. Zhang Q, Wang L, Zeng H, Lv Y, Huang Y. Epidemiology and risk factors in CKD patients with pulmonary hypertension: a retrospective study. BMC Nephrol. 2018;19:70 pmid:29554879
- 17. Kraemer M, Rode C, Wizemann V. Detection limit of methods to assess fluid status changes in dialysis patients. Kidney Int. 2006;69:1609–1620 pmid:16501488
- 18. Yoo HHB, Dos Reis R, Telini WM, Telini LR, Hueb JC, Bazan SGZ, et al. Association of pulmonary hypertension with inflammation and fluid overload in hemodialysis patients. Iran J Kidney Dis. 2017;11:303–308 pmid:28794293
- 19. Yoo HHB, Martin LC, Kochi AC, Rodrigues-Telini LS, Barretti P, Caramori JT, et al. Could albumin level explain the higher mortality in hemodialysis patients with pulmonary hypertension? BMC Nephrol. 2012;13:80 pmid:22867112
- 20. Han BG, Song SH, Yoo JS, Park H, Kim J, Choi E. Association between OH/ECW and echocardiographic parameters in CKD5 patients not undergoing dialysis. PLoS One. 2018;13:e0195202 pmid:29630661
- 21. Lang RM, Bierig M, Devereux RB, Flachskampf FA, Foster E, Pellikka PA, et al. Recommendations for chamber quantification: a report from the American Society of Echocardiography's Guidelines and Standards Committee and the Chamber Quantification Writing Group, developed in conjunction with the European Association of Echocardiography, a branch of the European Society of Cardiology. J Am Soc Echocardiogr. 2005;18:1440–1463 pmid:16376782
- 22. Nagueh SF, Appleton CP, Gillebert TC, Marino PN, Oh JK, Smiseth OA, et al. Recommendations for the evaluation of left ventricular diastolic function by echocardiography. Eur J Echocardiogr. 2009;10:165–193 https://doi.org/10.1093/ejechocard/jep007.
- 23. Rudski LG, Lai WW, Afilalo J, Hua L, Handschumacher MD, Chandrasekaran K, et al. Guidelines for the echocardiographic assessment of the right heart in adults: a report from the American Society of Echocardiography endorsed by the European Association of Echocardiography, a registered branch of the European Society of Cardiology, and the Canadian Society of Echocardiography. J Am Soc Echocardiogr. 2010;23:685–713; quiz 786–788 pmid:20620859
- 24. Hur E, Usta M, Toz H, Asci G, Wabel P, Kahvecioglu S, et al. Effect of fluid management guided by bioimpedance spectroscopy on cardiovascular parameters in hemodialysis patients: a randomized controlled trial. Am J Kidney Dis. 2013;61:957–965 pmid:23415416
- 25. Bozbas SS, Akcay S, Altin C, Bozbas H, Karacaglar E, Kanyilmaz S, et al. Pulmonary hypertension in patients with end-stage renal disease undergoing renal transplantation. Transplant Proc. 2009;41:2753–2756 pmid:19765426
- 26. Kawar B, Ellam T, Jackson C, Kiely DG. Pulmonary hypertension in renal disease: epidemiology, potential mechanisms and implications. Am J Nephrol. 2013;37:281–290 pmid:23548763
- 27. Abassi Z, Nakhoul F, Khankin E, Reisner SA, Yigla M. Pulmonary hypertension in chronic dialysis patients with arteriovenous fistula: pathogenesis and therapeutic prospective. Curr Opin Nephrol Hypertens. 2006;15:353–360 pmid:16775448
- 28. Etemadi J, Zolfaghari H, Firoozi R, Ardalan MR, Toufan M, Shoja MM, et al. Unexplained pulmonary hypertension in peritoneal dialysis and hemodialysis patients. Rev Port Pneumol. 2012;18:10–14 pmid:21920698
- 29. Unal A, Duran M, Tasdemir K, Oymak S, Sipahioglu MH, Tokgoz B, et al. Does arterio-venous fistula creation affects development of pulmonary hypertension in hemodialysis patients? Ren Fail. 2013;35:344–351 pmid:23356711
- 30. Poulikakos D, Theti D, Pau V, Banerjee D, Jones D. The impact of arteriovenous fistula creation in pulmonary hypertension: measurement of pulmonary pressures by right heart catheterization in a patient with respiratory failure following arteriovenous fistula creation. Hemodial Int. 2012;16:553–555 pmid:22360582
- 31. Kim JS, Yang JW, Yoo JS, Choi SO, Han BG. Association between E/e´ ratio and fluid overload in patients with predialysis chronic kidney disease. PLoS One. 2017;12:e0184764 pmid:28902883
- 32. Barberato SH, Mantilla DE, Misocami MA, Goncalves SM, Bignelli AT, Riella MC, et al. Effect of preload reduction by hemodialysis on left atrial volume and echocardiographic Doppler parameters in patients with end-stage renal disease. Am J Cardiol. 2004;94:1208–1210 pmid:15518627
- 33. Mutlak D, Aronson D, Lessick J, Reisner SA, Dabbah S, Agmon Y. Functional tricuspid regurgitation in patients with pulmonary hypertension: is pulmonary artery pressure the only determinant of regurgitation severity? Chest. 2009;135:115–121 pmid:18719061
- 34. Galie N, Hoeper MM, Humbert M, Torbicki A, Vachiery JL, Barbera JA, et al. Guidelines for the diagnosis and treatment of pulmonary hypertension: the Task Force for the Diagnosis and Treatment of Pulmonary Hypertension of the European Society of Cardiology (ESC) and the European Respiratory Society (ERS), endorsed by the International Society of Heart and Lung Transplantation (ISHLT). Eur Heart J. 2009;30:2493–2537 pmid:19713419
- 35. Ramasubbu K, Deswal A, Herdejurgen C, Aguilar D, Frost AE. A prospective echocardiographic evaluation of pulmonary hypertension in chronic hemodialysis patients in the United States: prevalence and clinical significance. Int J Gen Med. 2010;3:279–286 pmid:21042428
- 36. Casas-Aparicio G, Castillo-Martinez L, Orea-Tejeda A, Abasta-Jimenez M, Keirns-Davies C, Rebollar-Gonzalez V. The effect of successful kidney transplantation on ventricular dysfunction and pulmonary hypertension. Transplant Proc. 2010;42:3524–3528 pmid:21094809
- 37. Bozbas SS, Kanyilmaz S, Akcay S, Bozbas H, Altin C, Karacaglar E, et al. Renal transplant improves pulmonary hypertension in patients with end stage renal disease. Multidiscip Respir Med. 2011;6:155–160 pmid:22959121